Modeling Solar Eclipses at Extreme Ultra Violet Wavelengths and the Effects of Nonuniform Eclipse Shadow on the Ionosphere‐Thermosphere System

Mrak, Sebastijan; Zhu, Qingyu; Deng, Yue; Dammasch, I. E.; Dominique, Marie; Hairston, M. R.; Nishimura, Y.; Semeter, J. L.

doi:10.1029/2022ja031058

Cited by 4 publications

(10 citation statements)

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“…The eclipse-induced direct ionospheric effect includes a depletion of a few tenths in ionospheric electron density and TEC due to a local decrease of the photo-ionization (e.g., Afraimovich et al, 1998;Rishbeth, 1968;Tsai & Liu, 1999), as well as a cooling of several hundred K in plasma temperature resulting from the reduction of solar extreme ultraviolet (EUV) heating (e.g., Goncharenko et al, 2018;MacPherson et al, 2000). Moreover, the additional effects of solar eclipse include the enhanced downward plasma diffusion from the plasmasphere due to the reduction in the plasma equilibrium scale height and F region density (Huba & Drob, 2017;Wang et al, 2019), the modified neutral dynamics and associated electrodynamics in response to the eclipse-induced atmospheric cooling and composition changes (C.-H. Chen et al, 2019;Harding et al, 2018;St.-Maurice et al, 2011), as well as atmospheric bow waves and traveling ionospheric disturbances (TIDs) (e.g., Chimonas, 1970;Liu et al, 2011;Mrak et al, 2018Mrak et al, , 2022Nayak & Yiǧit, 2018;Sun et al, 2018;Zhang et al, 2017). Overall, the ionospheric response during a solar eclipse can be notably intricate due to the interplay of these dynamic photo-chemical, ambipolar diffusion, neutral wind, and electric field processes.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the additional effects of solar eclipse include the enhanced downward plasma diffusion from the plasmasphere due to the reduction in the plasma equilibrium scale height and F region density (Huba & Drob, 2017; Wang et al., 2019), the modified neutral dynamics and associated electrodynamics in response to the eclipse‐induced atmospheric cooling and composition changes (C.‐H. Chen et al., 2019; Harding et al., 2018; St.‐Maurice et al., 2011), as well as atmospheric bow waves and traveling ionospheric disturbances (TIDs) (e.g., Chimonas, 1970; Liu et al., 2011; Mrak et al., 2018, 2022; Nayak & Yiǧit, 2018; Sun et al., 2018; Zhang et al., 2017). Overall, the ionospheric response during a solar eclipse can be notably intricate due to the interplay of these dynamic photo‐chemical, ambipolar diffusion, neutral wind, and electric field processes.…”

Section: Introductionmentioning

confidence: 99%

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2‐D Total Electron Content and 3‐D Ionospheric Electron Density Variations During the 14 October 2023 Annular Solar Eclipse

Aa,

Coster,

Zhang

et al. 2024

JGR Space Physics

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This study investigates the ionospheric total electron content (TEC) responses in the 2‐D spatial domain and electron density variations in the 3‐D spatial domain during the annular solar eclipse on 14 October 2023, using ground‐based Global Navigation Satellite System (GNSS) observations, a novel TEC‐based ionospheric data assimilation system (TIDAS), ionosonde measurements, and satellite in situ data. The main results are summarized as follows: (a) The 2‐D TEC responses exhibited distinct latitudinal differences. The mid‐latitude ionosphere exhibited a more substantial TEC decrease of 25%–40% along with an extended recovery time of 3–4 hr. In contrast, the equatorial and low‐latitude ionosphere experienced a smaller TEC reduction of 10%–25% and a faster recovery time of 20–50 min. The minimal eclipse effect was observed near the northern equatorial ionization anomaly crest region. (b) The ionospheric electron density variations during the eclipse were effectively reconstructed by TIDAS data assimilation in the 3‐D domain, providing important altitude information with validity. (c) The ionospheric electron density variations showed a notable altitude‐dependent feature. The eclipse led to a substantial electron density reduction of 30%–50%, with the maximum depletion occurring around the ionospheric F2‐layer peak height (hmF2) of 250–350 km. The post‐eclipse recovery of electron density exhibited a relatively slower pace near the F2‐layer peak height than that at lower and higher altitudes.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

2‐D Total Electron Content and 3‐D Ionospheric Electron Density Variations During the 14 October 2023 Annular Solar Eclipse

Aa,

Coster,

Zhang

et al. 2024

JGR Space Physics

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“…It has been known for some time that observations of the ionosphere during a solar eclipse can be used as a method for studying various aspects of the ionosphere [1][2][3]. In recent decades, modern ionosondes have been used for such observations at relatively small time resolution during various eclipses; see, for example, [4][5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

“…In different studies, particular aspects of the ionosphere have been investigated: [4] and [6] focused on wave-like disturbances, [5] presented observations of plasma drift together with the effects on different International Union of Radio Science (URSI) parameters (f o E, f o F 2 , and hmF 2 ), and [7] used NmF 2 data derived from ionograms to validate physics-based modeling work.…”

Section: Introductionmentioning

confidence: 99%

“…As already described in [1,9], the quick movement of the lunar shadow results in a nonequilibrium condition in the ionosphere. In addition, the altitude dependency of the obscuration during an eclipse [10] and the effects of the non-uniformity of the solar disk in the EUV spectrum [7,11] have to be taken into account. Thus, it can be expected that not only the characteristics of the peaks of the ionospheric layers will be affected by a solar eclipse but also the entire shape of the electron density profile.…”

Section: Introductionmentioning

confidence: 99%

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The Changing Shape of the Ionosphere During a Solar Eclipse

2023

RSL

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Solar eclipses affect not only the ionospheric layers' peak densities and heights but also the general shape of the electron density profile. We revisit data obtained from the ionosonde in Dourbes, Belgium, during the solar eclipse of March 20, 2015. Previously, these observations were used to study the behavior of the F and E layer peaks and the plasma drifts. We investigate here which shape parameters of the bottom-side ionosphere were affected during this event. We find that the International Reference Ionosphere parameter B 0 is most affected, while B 1 is not affected by the eclipse at all. The scale height and slab thickness also show some effects but less so than B 0 .

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HF Radar Observations and Modeling of the Impact of the 8 April 2024 Total Solar Eclipse on the Ionosphere‐Thermosphere System

Kunduri,

Baker,

Ruohoniemi

et al. 2024

Geophysical Research Letters

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The path of totality of the 8 April 2024 solar eclipse traversed the fields‐of‐view of four US SuperDARN radars. This rare scenario provided an excellent opportunity to monitor the large‐scale ionospheric response to the eclipse. In this study, we present observations made by the Blackstone (BKS) SuperDARN radar and a Digisonde during the eclipse. Two striking effects were observed by the BKS radar: (a) the Doppler velocities associated with ground scatter coalesced into a pattern clearly organized by the line of totality, with a reversal in sign across this line, and, (b) a delay of 45 min between time of maximum obscuration and maximum effect on the skip distance. The skip distance estimated using a SAMI3 simulation of the eclipse did not however capture the asymmetric time‐delay. These observations suggest that the neutral atmosphere plays an important role in controlling ionospheric plasma dynamics, which were missing in SAMI3 simulations.

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Modeling Solar Eclipses at Extreme Ultra Violet Wavelengths and the Effects of Nonuniform Eclipse Shadow on the Ionosphere‐Thermosphere System

Cited by 4 publications

References 51 publications

2‐D Total Electron Content and 3‐D Ionospheric Electron Density Variations During the 14 October 2023 Annular Solar Eclipse

2‐D Total Electron Content and 3‐D Ionospheric Electron Density Variations During the 14 October 2023 Annular Solar Eclipse

The Changing Shape of the Ionosphere During a Solar Eclipse

HF Radar Observations and Modeling of the Impact of the 8 April 2024 Total Solar Eclipse on the Ionosphere‐Thermosphere System

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